Intrinsic Geometry and Analysis of Diffusion Processes and L∞-Variational Problems

Abstract

The aim of this paper is two-fold: First, we obtain a better understanding of the intrinsic distance of diffusion processes. Precisely, (i) for all n1, the diffusion matrix A is weak upper semicontinuous on if and only if the intrinsic differential and the local intrinsic distance structures coincide; (ii) if n=1, or if n2 and A is weak upper semicontinuous on , the intrinsic distance and differential structures always coincide; (iii) if n2 and A fails to be weak upper semicontinuous on , the (non-) coincidence of the intrinsic distance and differential structures depend on the geometry of the non-weak-upper-semicontinuity set of A. Second, for an arbitrary diffusion matrix A, we show that the intrinsic distance completely determines the absolute minimizer of the corresponding L∞-variational problem, and then obtain the existence and uniqueness for given boundary data. We also give an example of a diffusion matrix A for which there is an absolute minimizer that is not of class C1. When A is continuous, we also obtain the linear approximation property of the absolute minimizer.